Biogeochemical remediation approaches for PFAS contaminated environments. This project aims to identify and harvest microorganisms capable of directly or indirectly affecting PFOS or PFOA degradation in the environment. Fluorinated compounds such as PFOS and PFOA in firefighting foams are contaminants of concern now routinely detected in contaminated groundwater and soil globally. Understanding the role of microorganisms, and the biogeochemical processes they perform in relation to fluorinated c ....Biogeochemical remediation approaches for PFAS contaminated environments. This project aims to identify and harvest microorganisms capable of directly or indirectly affecting PFOS or PFOA degradation in the environment. Fluorinated compounds such as PFOS and PFOA in firefighting foams are contaminants of concern now routinely detected in contaminated groundwater and soil globally. Understanding the role of microorganisms, and the biogeochemical processes they perform in relation to fluorinated compounds, will inform handling of contaminated sites and lead to development of cost effective and sustainable remediation technologies. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100121
Funder
Australian Research Council
Funding Amount
$384,671.00
Summary
Genomic library infrastructure for ancient environmental samples. This project aims to enable automated genome recovery from diverse environmental samples, without contamination risk. For more than 100 years, environmental scientists have studied diverse organism / environment interactions using a variety of conceptual and technical tools. Recently, studies of ancient and historical DNA have come to complement these tools and to occupy a significant place in environmental studies conducted over ....Genomic library infrastructure for ancient environmental samples. This project aims to enable automated genome recovery from diverse environmental samples, without contamination risk. For more than 100 years, environmental scientists have studied diverse organism / environment interactions using a variety of conceptual and technical tools. Recently, studies of ancient and historical DNA have come to complement these tools and to occupy a significant place in environmental studies conducted over serial time. The project’s addition to the existing dual Ancient DNA complex facility at Griffith University will comprise two liquid handling workstations, each being housed in separate, self-contained, ancient DNA laboratories. The new facility will enable many researchers to have unprecedented access to an ancient DNA facility and a high level of technical support.Read moreRead less
Combining recycled water use, biofuel production and phytoremediation of contaminated land and biosolids. The storage of biosolids, by-products of sewage treatment, is an environmentally unsustainable practice exacerbated by the presence of inorganic and organic contaminants. Phytoremediation is a plant-based technology which is potentially a cost-effective option for progressive long-term and sustainable clean-up of contaminated soils and sediments. Combining metal extraction by plants with r ....Combining recycled water use, biofuel production and phytoremediation of contaminated land and biosolids. The storage of biosolids, by-products of sewage treatment, is an environmentally unsustainable practice exacerbated by the presence of inorganic and organic contaminants. Phytoremediation is a plant-based technology which is potentially a cost-effective option for progressive long-term and sustainable clean-up of contaminated soils and sediments. Combining metal extraction by plants with reuse of wastewater and the production of a biofuel will provide multiple benefits of a cleaner environment, water conservation, waste reduction, carbon capture and a reduction in fossil fuel use. Development of such a low-cost combined bioenergy/remediation system will be of considerable local/regional benefit and national significance.Read moreRead less
A novel method for controlling microbial concrete corrosion in sewers. This project plans to use a newly discovered, low-cost and environmental benign antimicrobial agent to develop an innovative technology to control the development of corrosion-inducing sewer biofilms. Concrete sewer corrosion is a long-standing and costly problem for the water industry. Microbial hydrogen sulfide oxidation on concrete surfaces plays a critical role. The technology will be designed to prevent corrosion of new ....A novel method for controlling microbial concrete corrosion in sewers. This project plans to use a newly discovered, low-cost and environmental benign antimicrobial agent to develop an innovative technology to control the development of corrosion-inducing sewer biofilms. Concrete sewer corrosion is a long-standing and costly problem for the water industry. Microbial hydrogen sulfide oxidation on concrete surfaces plays a critical role. The technology will be designed to prevent corrosion of new concrete sewers by adding a precursor chemical into the cement, or to slow down the corrosion of existing sewers by infrequently (once every one to few years) spraying the precursor chemical directly onto the concrete surface. Potentially, the project will substantially reduce sewer corrosion.Read moreRead less
Exploiting bacterial metal resistance machinery for metal ion nano-biosensors development. This project aims to integrate advanced materials chemistry, molecular biology, bio-electrochemical and synchrotron imaging approaches to understand the role of silver resistance machinery of bacteria in their ability to form silver nanoparticles. This aims to enable discovery of new metal-specific reductase enzymes. The fundamental biomolecular understanding of bacterial silver resistance will allow the u ....Exploiting bacterial metal resistance machinery for metal ion nano-biosensors development. This project aims to integrate advanced materials chemistry, molecular biology, bio-electrochemical and synchrotron imaging approaches to understand the role of silver resistance machinery of bacteria in their ability to form silver nanoparticles. This aims to enable discovery of new metal-specific reductase enzymes. The fundamental biomolecular understanding of bacterial silver resistance will allow the use of a silver-binding protein to develop a series of next-generation nano-biosensors. These biosensing platforms will provide high-throughput, cost-effective, selective, sensitive and continuous monitoring of heavy metal ions in effluents from mining and mineral processing industries in a real-time fashion.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100035
Funder
Australian Research Council
Funding Amount
$610,000.00
Summary
A single molecule real-time DNA sequencing facility. A single molecule real-time DNA sequencing facility: A PacBio SMRT sequencing facility will be established and used to accelerate ten specific research programs across a breadth of biological disciplines at two institutions. A specialised high throughput DNA sequencing technology called Single Molecule Real-Time (SMRT) sequencing developed by Pacific Biosciences (PacBio) is revolutionising biological research. SMRT sequencing allows researche ....A single molecule real-time DNA sequencing facility. A single molecule real-time DNA sequencing facility: A PacBio SMRT sequencing facility will be established and used to accelerate ten specific research programs across a breadth of biological disciplines at two institutions. A specialised high throughput DNA sequencing technology called Single Molecule Real-Time (SMRT) sequencing developed by Pacific Biosciences (PacBio) is revolutionising biological research. SMRT sequencing allows researchers to discover important information in DNA and RNA molecules that are missed by other modern DNA sequencing approaches. It is expected that this facility will also be a key infrastructure resource for the wider scientific community, helping to address fundamental questions in biology.Read moreRead less
Development of an anaerobic bioprocess for hexachlorobenzene destruction. This project will develop a biological process for destruction of a 10,000 tonne hexachlorobenzene stockpile in Sydney Australia. Development of a low energy bioprocess based on recently isolated bacteria will put an end to this ongoing health, environmental and industrial legacy issue and build expertise in bioprocessing for future applications.
In situ bioremediation solutions for Australia's organochlorine contaminated aquifers. This project will develop biological technologies to accelerate chlorinated solvent degradation in contaminated groundwater. Bacterial cultures developed in Australia will be injected into groundwater to enhance solvent degradation resulting in environmentally friendly and cost effective environmental restoration.
Synthetic Biology Derived Electroactive Whole Cell Microbial Biosensors. The aim of this project is to develop, using synthetic biology, electrically integrated microbial biosensors for the detection of heavy metals in the environment. Building on our existing technology, this project aims to produce novel ‘biobricks’ capable of electrically integrating electric microbes into real time environmental monitors for heavy metal contaminants. This expansion of synthetic biology, and integration of el ....Synthetic Biology Derived Electroactive Whole Cell Microbial Biosensors. The aim of this project is to develop, using synthetic biology, electrically integrated microbial biosensors for the detection of heavy metals in the environment. Building on our existing technology, this project aims to produce novel ‘biobricks’ capable of electrically integrating electric microbes into real time environmental monitors for heavy metal contaminants. This expansion of synthetic biology, and integration of electric bacteria into sensor systems, will result in a new platform technology that expands our abilities to protect the ecology, agriculture and health of terrestrial, marine and agricultural at risk areas from economic and environmental damage.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL180100036
Funder
Australian Research Council
Funding Amount
$3,011,916.00
Summary
Engineering microbes that increase coral climate resilience. This project aims to develop microbes which are able to enhance the climate resilience of corals. Coral reefs around the world are being lost at an alarming rate. Developing microbial symbionts to enhance coral climate resilience will give Australian and other coral reef ecosystems an increased chance of surviving the impact of climate change. The project will also enhance understanding of the functional roles of microbial symbionts of ....Engineering microbes that increase coral climate resilience. This project aims to develop microbes which are able to enhance the climate resilience of corals. Coral reefs around the world are being lost at an alarming rate. Developing microbial symbionts to enhance coral climate resilience will give Australian and other coral reef ecosystems an increased chance of surviving the impact of climate change. The project will also enhance understanding of the functional roles of microbial symbionts of corals, and advance the microbial symbiosis discipline globally. Expected outcomes include healthier coral reefs through the use of more climate resilient coral stock in reef conservation and restoration initiatives.Read moreRead less